Close Observation of the Evolution Process during Initial Stage of Triggered Lightning Based on Continuous Interferometer
Abstract
:1. Introduction
2. Experiment and Data
3. CINTF Error Calibration for the Initial Stage of the UPL
3.1. Basic Principle of CINTF Positioning
3.2. CINTF Error Calibration Method for the Initial Stage of the UPL
3.3. Analysis of CINTF Positioning Error in Initial Stage of UPL
4. Evolution Characteristics during Initial Stage of UPL: Results and Discussion
4.1. The Single Initial Process Form
4.2. The Multiple Initial Process Form
5. Conclusions
- The calibration method of a CINTF for positioning a specific short-range radiation source was proposed, and the calibration of the CINTF positioning results for the initial stage of the UPL was realized. The positioning error of the short-range radiation source caused by the basic principle of CINTF positioning was analyzed. When the azimuth angle and projection distance of the radiation source were constant, the vertical distance error of CINTF obviously increased with the increase in the elevation angle (height) of the radiation source. When the azimuth and height of the radiation source were constant, the vertical distance error of CINTF decreased obviously with the increase in the projection distance of the radiation source. For long-distance radiation sources, the vertical error of CINTF positioning was within 10 m, which shows the reliability of the conventional results of CINTF positioning. For a short-distance radiation source, the calibration method proposed in this paper improved the observation accuracy. When the elevation angles of the initial stage of the UPL were 40°, 50°, and 60°, the calibrated positioning error in altitude could be reduced by about 11 m, 14 m, and 20 m, respectively.
- The physical processed during the initial stage of the UPL of triggered lightning with a single initiation process and multiple initiation process were analyzed. When the rocket rose to a certain height, the CINTF began to detect the breakdown discharge process. The PCP signal, generated by a weak upward positive breakdown and a subsequent strong downward negative breakdown near the rising rocket tip, appeared in the current waveform. As the rocket continued to rise, the electric field near the rocket top increased, and PCP clusters appeared in the current waveform. At this time, the UPL began self-sustaining development, but the self-sustaining development disappeared quickly without continuous current. As the rocket continued to rise, the IPCP signal appeared, indicating that the UPL began self-sustaining development. The self-sustaining development after the IPCP could be short-term or continuous. After the short-term self-sustaining development, breakdown discharge could occur again near the rocket tip. It is also possible that the initial process could end completely and not develop into continuous self-sustaining development.
Author Contributions
Funding
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Chen, Z.; Zhang, Y.; Fan, Y.; Wang, J.; Lyu, W.; Zheng, D.; Pang, W. Close Observation of the Evolution Process during Initial Stage of Triggered Lightning Based on Continuous Interferometer. Remote Sens. 2022, 14, 863. https://doi.org/10.3390/rs14040863
Chen Z, Zhang Y, Fan Y, Wang J, Lyu W, Zheng D, Pang W. Close Observation of the Evolution Process during Initial Stage of Triggered Lightning Based on Continuous Interferometer. Remote Sensing. 2022; 14(4):863. https://doi.org/10.3390/rs14040863
Chicago/Turabian StyleChen, Zefang, Yang Zhang, Yanfeng Fan, Jingxuan Wang, Weitao Lyu, Dong Zheng, and Wenjing Pang. 2022. "Close Observation of the Evolution Process during Initial Stage of Triggered Lightning Based on Continuous Interferometer" Remote Sensing 14, no. 4: 863. https://doi.org/10.3390/rs14040863
APA StyleChen, Z., Zhang, Y., Fan, Y., Wang, J., Lyu, W., Zheng, D., & Pang, W. (2022). Close Observation of the Evolution Process during Initial Stage of Triggered Lightning Based on Continuous Interferometer. Remote Sensing, 14(4), 863. https://doi.org/10.3390/rs14040863